Oscillatory alignment phenomena in Rydberg-atom–rare-gas collisions

Abstract

Retention of orbital alignment during near-resonant energy transfer collisions of rare-gas projectiles with excited alkaline-earth-metal atoms is explored theoretically for scattering of Xe from Rydberg states of Ca. For such collisions, conventional interpretations of alignment phenomena, which are based on potential curves for a transient molecule thought to form during the collision, are not relevant. Theoretical partial magnetic sublevel cross sections for Ca**(4s17d D2→4s18p P1) transitions confirm the existence of alignment effects, as demonstrated experimentally by Spain et al. @J. Chem. Phys. 102, 9532 ~1995!#, at a mean relative velocity of 914 m/s. Theory further predicts heretofore unobserved oscillatory structures in these cross sections as a function of relative velocity and that these oscillations depend strongly on the initial magnetic quantum number of the Rydberg electron. @S1050-2947~98!50301-0#